Lecture

Approximation Landau: Ising Model

Related lectures (30)

Scaling & Renormalization in Statistical Mechanics

Explores scaling and renormalization in statistical mechanics, emphasizing critical points and invariant properties.

Explores Car-Parrinello molecular dynamics, a unified approach combining molecular dynamics and density-functional theory for simulating various systems, with a focus on historical background, technical details, and challenges in atomistic simulations.

Quantum Mechanics Evolution

Explains the representation for evolution in quantum mechanics and the application of path integrals.

Quantum Mechanics: Path Integral Formulation

Covers the path integral formulation of Quantum Mechanics, emphasizing its advantages and connection with statistical mechanics.

Quantum Mechanics: Double-Slit Experiment

Covers the postulates of Quantum Mechanics, the double-slit experiment, and the path integral formulation's significance in understanding quantum phenomena.

Renormalization Group in Field Theory

Explores the Renormalization Group in field theory, discussing scaling functions, critical exponents, and Gaussian fixed points.

Molecular dynamics under constraints

Explores molecular dynamics simulations under holonomic constraints, focusing on numerical integration and algorithm formulation.

Normed Spaces

Covers normed spaces, dual spaces, Banach spaces, Hilbert spaces, weak and strong convergence, reflexive spaces, and the Hahn-Banach theorem.

Statistical Physics: Entropy

Explores statistical physics concepts like equiprobable microstates, entropy, and canonical ensembles, with applications in quantum mechanics and semiconductor physics.

Statistical Definition of Entropy: Microstates and Macrostates

Covers microstates, macrostates, entropy, and density of states in statistical mechanics.

Thermophysical Properties: Models and Applications

Explores classical and quantum models to understand heat capacity in solids and discusses the relation between heat capacities at constant volume and pressure.

Quantum to Classical Mechanics: Fundamentals

Covers the transition from quantum to classical mechanics, statistical mechanics, Monte Carlo simulations, and molecular dynamics simulations.

Quantum Mechanics: Free Carrier Concentration and Maxwell Distribution

Discusses quantum mechanics principles, focusing on free carrier concentration and Maxwell distribution in metals and gases.

Path integrals and statistical mechanics

Explores path integral methods, partition functions, Trotter factorization, quantum-classical isomorphism, and multidimensional generalization in statistical mechanics.

Spherical Symmetry in Statistical Mechanics

Explores spherical symmetry in statistical mechanics and its role in phase transitions.

Path Integral Methods: Efficient Energy Estimators

Covers advanced path integral methods for deriving efficient energy estimators in molecular dynamics simulations.

Introduction to 3-State Ising Model

Covers the theoretical background and applications of the 3-state Ising model.

Classical and Quantum Mechanics: Foundations and Applications

Explores classical and quantum mechanics, covering observables, momentum, Hamiltonian, and the Schrödinger equation, as well as quantum chemistry and the Schrödinger's cat experiment.

Imaginary-Time Path Integrals

Covers Imaginary-Time Path Integrals, classical and quantum systems, convergence in simulations, and integration schemes for molecular dynamics.

Path Integral Methods: Convergence and Computational Techniques

Covers path integral methods, focusing on convergence and computational techniques for quantum systems.